// // QuartzAudio.m // // X Window bell support using CoreAudio or AppKit. // Greg Parker gparker@cs.stanford.edu 19 Feb 2001 // // Info about sine wave sound playback: // CoreAudio code derived from macosx-dev posting by Tim Wood // http://www.omnigroup.com/mailman/archive/macosx-dev/2000-May/002004.html // Smoothing transitions between sounds // http://www.wam.umd.edu/~mphoenix/dss/dss.html // /* * Copyright (c) 2001 Greg Parker. All Rights Reserved. * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in * all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL * THE ABOVE LISTED COPYRIGHT HOLDER(S) BE LIABLE FOR ANY CLAIM, DAMAGES OR * OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, * ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER * DEALINGS IN THE SOFTWARE. * * Except as contained in this notice, the name(s) of the above copyright * holders shall not be used in advertising or otherwise to promote the sale, * use or other dealings in this Software without prior written authorization. */ /* $XFree86: xc/programs/Xserver/hw/darwin/quartz/quartzAudio.c,v 1.2 2003/05/14 05:27:56 torrey Exp $ */ #include "quartzCommon.h" #include "quartzAudio.h" #include #include #include "inputstr.h" #include "extensions/XI.h" void NSBeep(); typedef struct QuartzAudioRec { double frequency; double amplitude; UInt32 curFrame; UInt32 remainingFrames; UInt32 totalFrames; UInt32 bytesPerFrame; double sampleRate; UInt32 fadeLength; UInt32 bufferByteCount; Boolean playing; pthread_mutex_t lock; // used to fade out interrupted sound and avoid 'pop' double prevFrequency; double prevAmplitude; UInt32 prevFrame; } QuartzAudioRec; static AudioDeviceID quartzAudioDevice = kAudioDeviceUnknown; static QuartzAudioRec data; /* * QuartzAudioEnvelope * Fade sound in and out to avoid pop. * Sounds with shorter duration will never reach full amplitude. Deal. */ static double QuartzAudioEnvelope( UInt32 curFrame, UInt32 totalFrames, UInt32 fadeLength ) { double fadeFrames = min(fadeLength, totalFrames / 2); if (fadeFrames < 1) return 0; if (curFrame < fadeFrames) { return curFrame / fadeFrames; } else if (curFrame > totalFrames - fadeFrames) { return (totalFrames-curFrame) / fadeFrames; } else { return 1.0; } } /* * QuartzFillBuffer * Fill this buffer with data and update the data position. * FIXME: this is ugly */ static void QuartzFillBuffer( AudioBuffer *audiobuffer, QuartzAudioRec *data ) { float *buffer, *b; unsigned int frame, frameCount; unsigned int bufferFrameCount; float multiplier, v; int i; buffer = (float *)audiobuffer->mData; bufferFrameCount = audiobuffer->mDataByteSize / data->bytesPerFrame; frameCount = min(bufferFrameCount, data->remainingFrames); // Fade out previous sine wave, if any. b = buffer; if (data->prevFrame) { multiplier = 2*M_PI*(data->prevFrequency/data->sampleRate); for (frame = 0; frame < data->fadeLength; frame++) { v = data->prevAmplitude * QuartzAudioEnvelope(frame+data->fadeLength, 2*data->fadeLength, data->fadeLength) * sin(multiplier * (data->prevFrame+frame)); for (i = 0; i < audiobuffer->mNumberChannels; i++) { *b++ = v; } } // no more prev fade data->prevFrame = 0; // adjust for space eaten by prev fade buffer += audiobuffer->mNumberChannels*frame; bufferFrameCount -= frame; frameCount = min(bufferFrameCount, data->remainingFrames); } // Write a sine wave with the specified frequency and amplitude multiplier = 2*M_PI*(data->frequency/data->sampleRate); for (frame = 0; frame < frameCount; frame++) { v = data->amplitude * QuartzAudioEnvelope(data->curFrame+frame, data->totalFrames, data->fadeLength) * sin(multiplier * (data->curFrame+frame)); for (i = 0; i < audiobuffer->mNumberChannels; i++) { *b++ = v; } } // Zero out the rest of the buffer, if any memset(b, 0, sizeof(float) * audiobuffer->mNumberChannels * (bufferFrameCount-frame)); data->curFrame += frameCount; data->remainingFrames -= frameCount; if (data->remainingFrames == 0) { data->playing = FALSE; data->curFrame = 0; } } /* * QuartzAudioIOProc * Callback function for audio playback. * FIXME: use inOutputTime to correct for skipping */ static OSStatus QuartzAudioIOProc( AudioDeviceID inDevice, const AudioTimeStamp *inNow, const AudioBufferList *inInputData, const AudioTimeStamp *inInputTime, AudioBufferList *outOutputData, const AudioTimeStamp *inOutputTime, void *inClientData ) { QuartzAudioRec *data = (QuartzAudioRec *)inClientData; int i; Boolean wasPlaying; pthread_mutex_lock(&data->lock); wasPlaying = data->playing; for (i = 0; i < outOutputData->mNumberBuffers; i++) { if (data->playing) { QuartzFillBuffer(outOutputData->mBuffers+i, data); } else { memset(outOutputData->mBuffers[i].mData, 0, outOutputData->mBuffers[i].mDataByteSize); } } if (wasPlaying && !data->playing) { OSStatus err; err = AudioDeviceStop(inDevice, QuartzAudioIOProc); } pthread_mutex_unlock(&data->lock); return 0; } /* * QuartzCoreAudioBell * Play a tone using the CoreAudio API */ static void QuartzCoreAudioBell( int volume, // volume is % of max int pitch, // pitch is Hz int duration ) // duration is milliseconds { if (quartzAudioDevice == kAudioDeviceUnknown) return; pthread_mutex_lock(&data.lock); // fade previous sound, if any data.prevFrequency = data.frequency; data.prevAmplitude = data.amplitude; data.prevFrame = data.curFrame; // set new sound data.frequency = pitch; data.amplitude = volume / 100.0; data.curFrame = 0; data.totalFrames = (int)(data.sampleRate * duration / 1000.0); data.remainingFrames = data.totalFrames; if (! data.playing) { OSStatus status; status = AudioDeviceStart(quartzAudioDevice, QuartzAudioIOProc); if (status) { ErrorF("QuartzAudioBell: AudioDeviceStart returned %d\n", status); } else { data.playing = TRUE; } } pthread_mutex_unlock(&data.lock); } /* * DarwinModeBell * Ring the bell */ void DarwinModeBell( int volume, // volume in percent of max DeviceIntPtr pDevice, pointer ctrl, int class ) { int pitch; // pitch in Hz int duration; // duration in milliseconds if (class == BellFeedbackClass) { pitch = ((BellCtrl*)ctrl)->pitch; duration = ((BellCtrl*)ctrl)->duration; } else if (class == KbdFeedbackClass) { pitch = ((KeybdCtrl*)ctrl)->bell_pitch; duration = ((KeybdCtrl*)ctrl)->bell_duration; } else { ErrorF("QuartzBell: bad bell class %d\n", class); return; } if (quartzUseSysBeep) { if (volume) NSBeep(); } else { QuartzCoreAudioBell(volume, pitch, duration); } } /* * QuartzAudioInit * Prepare to play the bell with the CoreAudio API */ void QuartzAudioInit(void) { UInt32 propertySize; OSStatus status; AudioDeviceID outputDevice; AudioStreamBasicDescription outputStreamDescription; double sampleRate; // Get the default output device propertySize = sizeof(outputDevice); status = AudioHardwareGetProperty( kAudioHardwarePropertyDefaultOutputDevice, &propertySize, &outputDevice); if (status) { ErrorF("QuartzAudioInit: AudioHardwareGetProperty returned %d\n", status); return; } if (outputDevice == kAudioDeviceUnknown) { ErrorF("QuartzAudioInit: No audio output devices available.\n"); return; } // Get the basic device description propertySize = sizeof(outputStreamDescription); status = AudioDeviceGetProperty(outputDevice, 0, FALSE, kAudioDevicePropertyStreamFormat, &propertySize, &outputStreamDescription); if (status) { ErrorF("QuartzAudioInit: GetProperty(stream format) returned %d\n", status); return; } sampleRate = outputStreamDescription.mSampleRate; // Fill in the playback data data.frequency = 0; data.amplitude = 0; data.curFrame = 0; data.remainingFrames = 0; data.bytesPerFrame = outputStreamDescription.mBytesPerFrame; data.sampleRate = sampleRate; // data.bufferByteCount = bufferByteCount; data.playing = FALSE; data.prevAmplitude = 0; data.prevFrame = 0; data.prevFrequency = 0; data.fadeLength = data.sampleRate / 200; pthread_mutex_init(&data.lock, NULL); // fixme error check // fixme assert fadeLength